Reciprocating power tool

ABSTRACT

It is an object of the invention to provide a useful technique for reducing vibration of a handgrip and improving the cutting efficiency while achieving weight reduction of a reciprocating power tool. According to the invention, a representative reciprocating power tool is provided to comprise a body, a tool bit, an actuating mechanism, a handgrip. The handgrip and the body can rotate with respect to each other via a pivot in a direction crossing the direction of reciprocating linear motion of the tool bit. An elastic element is disposed between the handgrip and the body and serves to absorb vibration transmitted from the body to the handgrip by elastically receiving the relative rotation of the handgrip and the body. According to the invention, vibration in the handgrip can be reduced and the cutting efficiency can be improved without complicating the construction.

This is a Continuation of application Ser. No. 11/289,547 filed Nov. 30,2005. The disclosure of the prior application is hereby incorporated byreference herein in its entirety.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a reciprocating power tool such as areciprocating saw and more particularly, to a technique for reducingvibration in cutting a workpiece and a cutting technique when thereciprocating power tool is in operation.

2. Description of the Related Art

Japanese non-examined laid-open Patent Publication No. 2001-9632(hereinafter referred to as “D1”) discloses an electric reciprocatingsaw as an example of a reciprocating power tool. The known reciprocatingsaw includes a motion converting mechanism for causing a slider toreciprocate in the longitudinal direction. A counter weight is providedin the motion converting mechanism. When the slider reciprocates, thecounter weight reciprocates in a direction opposite to the reciprocatingdirection of the slider, with a 180° phase shift with respect to theslider. As a result, vibration of the reciprocating saw caused by thereciprocating movement of the slider can be reduced.

Further, Japanese non-examined laid-open Patent Publication No. 06-79701(hereinafter referred to as “D2”) discloses an electric reciprocatingsaw having a first motion converting mechanism for converting therotating output of a motor into reciprocating linear motion in thelongitudinal direction of the slider and a second motion convertingmechanism for converting the rotating output of the motor into swingingmotion in the vertical direction of the slider. In the reciprocating sawhaving such a construction, the tool bit or the blade supported by theslider not only linearly reciprocates in the longitudinal direction, butswings in the vertical direction, whereby the cutting efficiency can beincreased.

In the reciprocating saw as disclosed in D1, because the counter weightis additionally provided for vibration reduction in the motionconverting mechanism, the weight of the reciprocating saw itself isincreased by the weight of the counter weight. Therefore, furtherimprovement is desired in this respect. On the other hand, in thereciprocating saw disclosed in D2, the actuating mechanism for the bladeincludes the first motion converting mechanism for causing the blade tolinearly reciprocate and the second motion converting mechanism forcausing the blade to swing in the vertical direction. Therefore, theactuating mechanism is complicated in structure, the weight of theentire reciprocating saw is increased, and the size of the entirehousing for housing these mechanisms is increased. Therefore, furtherimprovement is also desired in this respect.

SUMMARY OF THE INVENTION

Accordingly, it is an object of the invention to provide a usefultechnique for reducing vibration of a handgrip and improving the cuttingefficiency while achieving weight reduction of a reciprocating powertool.

The above-described problem can be solved by the features of claimedinvention. According to the invention, a representative reciprocatingpower tool is provided to comprise a body, a tool bit disposed in thetip end region of the body, an actuating mechanism disposed within thebody to cause the tool bit to linearly reciprocate, a handgrip disposedon the rear end of the body on the side opposite to the tool bit. The“reciprocating power tool” according to the invention may includevarious power tools such as a reciprocating saw and a jig saw, to beused to cut a workpiece of various materials such as wood and metal. The“tool bit” typically comprises a blade which is formed of a steel sheetand has teeth continuously formed on the edge of the steel sheet.

According to the invention, the handgrip and the body are coupled toeach other such that the handgrip and the body can rotate with respectto each other via a pivot in a direction crossing the direction ofreciprocating linear motion of the tool bit. The tool bit swingstogether with the body with respect to the handgrip being held by a userof the power tool, while the tool bit linearly reciprocates with respectto the body via the actuating mechanism. When the tool bit linearlyreciprocates with respect to the body with the handgrip held by a user,an inertial force acts upon the body. By this inertial force, the toolbit swings on the pivot together with the body with respect to thehandgrip. The angle of inclination of the reciprocating tool bit ischanged by the combined motion of the tool bit that swings whilereciprocating. Such change of the inclination angle of the tool bit canincrease the cutting efficiency.

The swinging motion of the tool bit is realized with a simpleconstruction in which the body is coupled to the handgrip via the pivot.Therefore, compared with the prior arts in which a combination ofseveral functional components driven by a motor is used as a motionconverting mechanism in order to cause the tool bit to swing, theconstruction can be simpler and lighter in weight. Thus, the weightreduction of the reciprocating power tool can be achieved. Further, thebody can be made thinner. Therefore, ease of use can be enhanced inperforming a cutting operation while holding the handgrip by one handand holding the tip end region of the body by the other hand.

According to the invention, an elastic element is disposed between thehandgrip and the body and serves to absorb vibration transmitted fromthe body to the handgrip by elastically receiving the relative rotationof the handgrip and the body. The “elastic element” comprises a rubberor a spring. The manner in which the “elastic element is disposed”suitably includes both the manner in which the elastic element isdisposed apart from the pivot and the manner in which the elasticelement is disposed on the axis of the pivot. The elastic elementdisposed between the handgrip and the body absorbs and reduces vibrationcaused in the body and transmitted to the handgrip, by elasticdeformation of the elastic element. Such vibration reduction by usingthe elastic element is more effective for weight reduction of thereciprocating power tool, compared with the known art that uses acounter weight.

Thus, according to the invention, vibration in the handgrip can bereduced and the cutting efficiency can be improved without complicatingthe construction. Other objects, features and advantages of the presentinvention will be readily understood after reading the followingdetailed description together with the accompanying drawings and theclaims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a sectional view showing an entire reciprocating saw having avibration-proof handgrip according to an embodiment of the invention.

FIG. 2 is a sectional view showing a rotatable connection between afixed part and a moving grip part.

FIG. 3 is a sectional view taken along line III-III in FIG. 1.

FIG. 4 is a view showing the inclination of a blade when a slider is inthe bottom dead center.

FIG. 5 is a view showing the inclination of the blade when the slider isin the upper dead center.

FIG. 6 is a sectional view showing an entire reciprocating saw having anormal handgrip.

DETAILED DESCRIPTION OF THE INVENTION

Each of the additional features and method steps disclosed above andbelow may be utilized separately or in conjunction with other featuresand method steps to provide and manufacture improved reciprocating powertools and method for using such reciprocating power tools and devicesutilized therein. Representative examples of the present invention,which examples utilized many of these additional features and methodsteps in conjunction, will now be described in detail with reference tothe drawings. This detailed description is merely intended to teach aperson skilled in the art further details for practicing preferredaspects of the present teachings and is not intended to limit the scopeof the invention. Only the claims define the scope of the claimedinvention. Therefore, combinations of features and steps disclosedwithin the following detailed description may not be necessary topractice the invention in the broadest sense, and are instead taughtmerely to particularly describe some representative examples of theinvention, which detailed description will now be given with referenceto the accompanying drawings.

A representative embodiment of the present invention will now bedescribed with reference to the drawings. As shown in FIG. 1, areciprocating saw 101 as arepresentative embodiment of a reciprocatingpower tool according to the invention comprises a body 103, a slider107, a blade 111 and a handgrip 105. The slider 107 projects from thebody 103 and the blade 111 is detachably mounted to a chuck 109 on theend of the slider 107 and cuts a workpiece (not particularly shown). Theblade 111 is a feature that corresponds to the “tool bit” according tothe invention. The body 103 includes a motor housing 103 a and a gearhousing 103 b connected to the front end of the motor housing 103 a Inthe present embodiment, for the sake of convenience of explanation, theside of the blade 111 is taken as the front side and the side of thehandgrip 105 as the rear side in the following description.

The motor housing 103 a of the body 103 houses a driving motor 113. Thedriving motor 113 is driven when the user depresses a trigger switch115. The blade 111 then reciprocates in the longitudinal directiontogether with the slider 107 and the chuck 109 and can cut a workpiece.The slider 107, the chuck 109 and the blade 111 form a moving part. Theslider 107 is supported via a bearing 108 in the gear housing 103 b suchthat the slider 107 can reciprocate in its longitudinal direction. Theslider 107 is connected to a motor shaft 117 via a motion convertingmechanism 121 disposed within the gear housing 103 b. The motionconverting mechanism 121 is a feature that corresponds to the “actuatingmechanism” according to the invention.

The motion converting mechanism 121 converts the rotational motion ofthe motor shaft 117 into the reciprocating motion in the longitudinaldirection of the slider 107. The motion converting mechanism 121comprises a bevel gear 123, a crank pin 129 and a slider block 131. Thebevel gear 123 engages with a pinion 119 of the motor shaft 117. Thebevel gear 123 is mounted to a fixed shaft 125 that is fixed to the gearhousing 103 b, via a bearing 127 and can rotate within a horizontalplane. The crank pin 129 is mounted on the upper surface of the bevelgear 123 at a position shifted a predetermined distance from the centerof rotation of the bevel gear 123. The lower end of the crank pin 129 isfixedly mounted by press-fitting into a pin mounting hole that is formedin the bevel gear 123. The upper end of the crank pin 129 is fitted inthe slider block 131 that is formed in the slider 107, via a bearing133. Thus, the crank pin 129 can rotate with respect to the slider 107.

The slider block 131 has a guide groove 131 a extending in a directioncrossing the longitudinal direction of the slider 107. The crank pin 129can move with respect to the slider block 131 along the guide groove 131a via the bearing 133 that is fitted in the guide groove 131 a. Withrespect to the revolving motion of the crank pin 129 around the fixedshaft 125, components of the motion in the direction crossing thelongitudinal direction of the slider 107 within a horizontal planeescape into the guide groove 131 a and only components of the motion inthe longitudinal direction of the slider 107 are transmitted to theslider 107. The slider 107 is thus allowed to reciprocate only in itslongitudinal direction. Further, a shoe 106 is mounted on the end of thebody 103. The user presses the shoe 106 against the workpiece whileholding the handgrip 105 during cutting operation.

The construction of the handgrip 105 and the construction for mountingthe handgrip 105 to the body 103 will now be explained with reference toFIGS. 1 to 3. Vibration is caused in the body 103 during operation ofcutting a workpiece with the reciprocating saw 101. According to therepresentative embodiment, in order to reduce transmission of thisvibration to the handgrip 105, the handgrip 105 is constructed asfollows. The handgrip 105 is a D-type handgrip which is generallyD-shaped in side view. The handgrip 105 is hollow and generallyrectangular in section. An opening 141 is formed in the front upperregion of the handgrip 105 and opens to the front. In order to mount thehandgrip 105 to the motor housing 103 a, the opening 141 is fitted onthe rear end of the body 103 or a grip mounting portion 143 formed inthe rear end portion of the motor housing 103 a.

The handgrip 105 has a two-part structure which is divided into halvesalong a vertical plane parallel to the axis of the slider 107.Specifically, the handgrip 105 includes right and left halves 105 a, 105b (see FIGS. 2 and 3). The right and left halves 105 a, 105 b are buttedagainst each other from the sides in such a manner that the region ofthe opening 141 covers the grip mounting portion 143. In this state, thehalves 105 a, 105 b are joined by clamping screws 144 (see FIG. 1) atseveral points on the edge portions of the halves 105 a, 105 b. Thus,the handgrip 105 is fixedly mounted on the grip mounting portion 143.The handgrip 105 can be detached from the grip mounting portion 143 byunscrewing the clamping screws 144 so as to disjoin the halves 105 a,105 b from the grip mounting portion 143. Specifically, the handgrip 105is constructed to be detachably mounted to the body 103. Further, asshown in FIG. 1, an engaging portion 142 is formed on the engagementsurfaces between the opening 141 and the grip mounting portion 143. Therespective engaging portions 142 have projections and depressions andengage with each other. By the engagement of the engaging portions 142,the handgrip 105 is prevented from falling off rearward from the body103.

Further, the handgrip 105 is partitioned into two forward and rearwardparts. The forward part comprises a fixed part 145 a mounted to themotor housing 103 a, and the rearward part comprises a moving grip part145 b that a user grips. The fixed part 145 a is mounted to the motorhousing 103 a in such a manner as mentioned in the preceding paragraph.One end (lower end) of the moving grip part 145 b is rotatably connectedto one end (lower end) of the fixed part 145 a via a pivot 147. Theother end (upper end) of the moving grip part 145 b is elasticallyconnected to the other end (upper end) of the fixed part 145 a via acompression coil spring 149. The compression coil spring 149 is afeature that corresponds to the “elastic element” in the presentinvention. With the above-mentioned construction, the moving grip part145 b and the body 103 can rotate vertically or in a direction crossingthe direction of the reciprocating movement of the blade 111 about thepivot 147 with respect to each other. Thus, the vibration-proof handgrip105 is formed with a construction in which the moving grip part 145 b isrotatably connected at its lower end to the fixed part 145 a via thepivot 147 and connected at its upper end to the fixed part 145 a via thecompression coil spring 149.

FIG. 2 shows a rotatable connection between the fixed part 145 a and themoving grip part 145 b. As shown, the right and left halves 105 a, 105 bof the handgrip 105 are butt-joined to each other, and the side lowerend portion of the fixed part 145 a is fitted over the side lower endportion of the moving grip part 145 b. In this state, the side endportion of the fixed part 145 a is fastened to the side end portion ofthe moving grip part 145 b via a bush 147 a by amounting screw 147 b. Inthis manner, the fixed part 145 a and the moving grip part 145 b arerotatably connected to each other. The bush 147 a and the mounting screw147 b form the pivot 147.

Further, as shown in FIG. 1, the compression coil spring 149 is disposedforward of the pivot 147 and on the axis of the slider 107 and arrangedsuch that the biasing direction of the compression coil spring 149 istangential to the rotation around the pivot 147. Specifically, thecompression coil spring 149 is disposed on the forward decline betweenthe fixed part 145 a and the moving grip part 145 b in the handgrip 105.FIG. 3 is a sectional view showing the mounting portion for mounting thecompression coil spring 149. As shown in FIGS. 1 and 3, a rectangulartubular portion 151 having a circular bore is formed in the front upperportion of the moving grip part 145 b and receives the compression coilspring 149. The tubular portion 151 projects forward on the decline andis movably inserted into a space 153 that is formed in the fixed part145 a A circular projection (pin) 151 a is formed on the right and leftsides of the tubular portion 151 and is slidably engaged with a guidegroove 153 a in the space 153. (The guide groove 153 a is formed in aportion of the fixed part 145 a which defines and faces the space 153.)The guide groove 153 a extends to a predetermined length in theinclining direction of the tubular portion 151. Thus, the fixed part 145a and the moving grip part 145 b are allowed to pivot within the lengthrange of the guide groove 153 a with respect to each other. Further, oneend of the compression coil spring 149 rests on the bottom of the boreof the tubular portion 151, while the other end rests on the bottom ofthe space 153.

A dynamic vibration reducer 161 is disposed rearward of the compressioncoil spring 149 within the hollow portion of the moving grip part 145 band serves to reduce vibration of the moving grip part 145 b. Thedynamic vibration reducer 161 is positioned so as to reduce vibration inthe reciprocating direction (longitudinal direction) of the blade 111,which vibration is transmitted from the body 103 to the moving grip part145 b. The dynamic vibration reducer 161 includes a guide rod 163, aweight 165 and a biasing spring 167. The guide rod 163 extends in thelongitudinal direction of the slider 107. The weight 165 is mounted onthe guide rod 163 and can move in the axial direction. The biasingspring 167 is disposed on the both sides of the weight 165 in the axialdirection. The biasing spring 167 applies a spring force to the weight165 between the weight 165 and the moving grip part 145 b (rod mountingportion) when the weight 165 moves in the axial direction of the guiderod 163.

Further, in the reciprocating saw 101 according to the representativeembodiment, the above-mentioned vibration-proof handgrip 105 can beintegrally replaced with a normal handgrip of standard specificationwhich does not have a vibration reducing function. FIG. 6 shows thereciprocating saw 101 in which a normal handgrip 205 is attached to thebody 103. The vibration-proof handgrip 105 and the normal handgrip 205have a construction for mounting to the motor housing 103 a in commonsuch that the handgrips 105, 205 can be integrally replaced with eachother. Specifically, the handgrip 205 has a two-part structure which isdivided into halves along a vertical plane parallel to the axis of theslider 107 and thus includes right and left halves 205 a, 205 b. Theright and left halves 205 a, 205 b are butted against each other fromthe sides in such a manner that the front upper portion of the handgrip205 covers the grip mounting portion 143. In this state, the halves 205a, 205 b are joined by clamping screws 244 at several points on the edgeportions of the halves 205 a, 205 b. Thus, the handgrip 205 isdetachably mounted on the grip mounting portion 143.

Operation and usage of the reciprocating saw 101 constructed asdescribed above will now be explained. When the user depresses thetrigger switch 115 disposed on the moving grip part 145 b of thehandgrip 105 of the reciprocating saw 101 as shown in FIG. 1, thedriving motor 113 is driven, and the bevel gear 123 is rotated aroundthe fixed shaft 125 within a horizontal plane via the motor shaft 117and the pinion 119. Then, the crank pin 129 revolves around the fixedshaft 125. As a result, the slider 107 reciprocates in the longitudinaldirection between the top dead center and the bottom dead center via theslider block 137. Thus, the blade 111 that is coupled to the chuck 109on the end of the slider 107 reciprocates and is allowed to cut theworkpiece.

The user presses the shoe 106 against the workpiece to be cut and cutsthe workpiece in this state from above by the reciprocating blade 111.At this time, the blade 111 can be smoothly operated even if the userobliquely presses the moving grip part 145 b against the tool body 103,because the fixed part 145 a and the moving grip part 145 b arerotatably connected to each other via the pivot 147.

During actuation of the blade 111 or during operation of cutting aworkpiece by the blade 111, vibration is caused in the reciprocating saw101. The handgrip 105 is segmented into the fixed part 145 a and themoving grip part 145 b. The lower end of the moving grip part 145 b isrotatably connected to the fixed part 145 a via the pivot 147, and theupper end of the moving grip part 145 b is elastically connected to thefixed part 145 a via the compression coil spring 149. With suchconstruction, vibration caused in the body 103 and transmitted to themoving grip part 145 b can be absorbed and reduced by the spring forceof the compression coil spring 149. The compression coil spring 149 isdisposed generally on the line of reciprocating movement of the blade111 and tangentially to the rotation around the pivot 147. Therefore,the compression coil spring 149 can efficiently absorb the longitudinalvibration which is transmitted from the body 103 to the moving grip part145 b of the handgrip 105.

Amount of vibration was measured in each of the longitudinal, verticaland lateral directions of the handgrips 105, 205 and in the three-axisresultant, using the reciprocating saw 101 with the vibration-proofhandgrip 105 as shown in FIG. 1 and the reciprocating saw 101 with thenormal handgrip 205 of standard specification without a vibrationreducing function as shown in FIG. 6. As a result, the vibration valuesof the vibration-proof handgrip 105 (the moving grip part 145 b) werelower than the normal handgrip 205 in all the measurements other than inthe vertical direction, i.e. in the longitudinal and lateral directionsand in the three-axis resultant. Thus, the vibration-proof handgrip 105was proved to have a vibration reducing effect. Further, it was alsoconfirmed that the same vibration reducing effect can be achievedwhether under unloaded or loaded conditions and whether in woodworkingor in metalworking. Thus, according to the embodiment, thevibration-proof handgrip 105 was proved to have an adequate vibrationreducing effect as a whole.

Further, according to this embodiment, during cutting operation, whenthe blade 111 linearly reciprocates together with the slider 107 and thechuck 109 in the longitudinal direction between the top dead center andthe bottom dead center, the blade 111 vertically swings on the pivot 147together with the body 103. Specifically, when the blade 111 linearlyreciprocates, an inertial force acts upon the body 103 and thecompression coil spring 149 receives this inertial force. The blade 111then vertically swings on the pivot 147 while deforming the compressioncoil spring 149. As a result, the blade 111 performs a combined motionof the reciprocating linear motion and the vertical swinging motion onthe pivot 147, or a circular arc motion in the cutting direction(longitudinal direction). Such circular arc motion of the blade 111causes a change in the angle of inclination of the reciprocating blade111. By virtue of the angle change of the blade 111, the cuttingefficiency is enhanced.

When the slider 107 moves from the top dead center to the bottom deadcenter or when the blade 111 retracts to be drawn leftward as viewed inFIG. 1 to cut the workpiece, the angle of inclination of the blade 111defined by the angle between the horizontal axis and the axis of theslider 107 gradually increases. In other words, the tip end of the blade111 is oriented upward. By such increase in the blade inclination, thenumber of teeth of the blade 111 which touch the workpiece duringcutting operation is reduced compared with the case in which the blade111 is moved linearly. Therefore, the teeth of the blade 111 can readilydig into the workpiece, so that the cutting efficiency can be improved.On the other hand, when the slider 107 moves from the bottom dead centerto the top dead center (the blade 111 is pushed), the angle ofinclination of the blade 111 gradually decreases. FIG. 4 shows the blade111 inclined at an angle of θ1 (for example, 1°) when the slider 107 isin the bottom dead center. FIG. 5 shows the blade 111 inclined at anangle of θ2 (for example, −5°) when the slider 107 is in the top deadcenter. Thus, according to the embodiment, when the blade 111 linearlyreciprocates, the blade 111 is caused to vertically swing together withthe body 103, so that the angle of inclination of the blade 111 changes.As a result, the cutting efficiency can be improved. The angle ofinclination of the blade 111 tends to vary in a greater degree as theload during cutting operation increases.

The reciprocating saw 101 according to the embodiment is configured toachieve vibration reduction of the handgrip 105 and greater cuttingefficiency by improving the construction for mounting the handgrip 105.Therefore, in contrast to the known arts in which a functional componentis additionally provided in the blade actuating mechanism in order toreduce vibration and/or improve the cutting efficiency, thereciprocating saw 101 can be simpler in construction and lighter inweight. Further, the motor housing 103 a and the gear housing 103 bwhich form the body 103 can be made thinner. Therefore, ease of use canbe enhanced in performing a cutting operation while holding the movinggrip part 145 b by one hand and holding the tip end region of the body103 by the other hand.

Further, because each of the vibration-proof handgrip 105 and the normalhandgrip 205 of standard specification can be detachably mounted to thebody 103 and can be replaced with the other, the reciprocating saw 101can be provided in high-efficiency mode and in standard-efficiency mode.

Further, the dynamic vibration reducer 161 is provided within the movinggrip part 145 b of the handgrip 105. Therefore, the dynamic vibrationreducer 161 in the moving grip part 145 b performs a vibration reducingfunction with respect to vibrations of the moving grip part 145 b whichcannot be absorbed any more by the compression coil spring 149.Specifically, vibration reducing elements in the dynamic vibrationreducer 161, i.e. the weight 165 and the biasing springs 167 cooperateto passively reduce vibration of the moving grip part 145 b of thereciprocating saw 101 on which a predetermined external force(vibration) is exerted. Thus, the vibration of the reciprocating saw 101can be effectively alleviated or reduced. Further, when vibrationscaused when the blade 111 reciprocates have a low frequency at thesource so that the compression coil spring 149 can not appropriatelyabsorb such vibrations, the dynamic vibration reducer 161 can alleviatesuch vibrations. Thus, provision of the dynamic vibration reducer 161can further reduce the vibration of the moving grip part 145 b, so thatthe ease of use of the reciprocating saw 101 can be further enhanced. Inthis case, the dynamic vibration reducer 161 is disposed on the line ofreciprocating movement of the blade 111. Therefore, the dynamicvibration reducer 161 can efficiently perform the vibration reducingfunction, and generation of vibration by actuation of the dynamicvibration reducer 161 can be avoided. Thus, the dynamic vibrationreducer 161 can effectively perform the vibration reducing function.

Further, rubber may be used instead of the compression coil spring 149as an elastic element according to the representative embodiment.Further, according to the embodiment, the reciprocating saw 101 has beendescribed as an example of the reciprocating power tool, but thisinvention may be applied to tools, such as a jig saw, which performs acutting operation on a workpiece by reciprocating. Further, in thisembodiment, the handgrip 105 has been described as having a D-shape, butit is not limited to this shape.

It is explicitly stated that all features disclosed in the descriptionand/or the claims are intended to be disclosed separately andindependently from each other for the purpose of original disclosure aswell as for the purpose of restricting the claimed invention independentof the composition of the features in the embodiments and/or the claims.It is explicitly stated that all value ranges or indications of groupsof entities disclose every possible intermediate value or intermediateentity for the purpose of original disclosure as well as for the purposeof restricting the claimed invention, in particular as limits of valueranges.

1. A reciprocating power tool defined by a reciprocating saw,comprising: a body, a tool bit disposed in a tip end region of the body,the tool bit being defined by a saw blade; a motor disposed within thebody, the motor causing the tool bit to linearly reciprocate; a handgripdisposed on a rear end of the body on the side opposite to the tool bit,wherein the handgrip and the body are coupled to each other such thatthe handgrip and the body can rotate with respect to each other via afixed axis pivot about a rotational axis extending in a directionperpendicular to a direction of reciprocating linear motion of the toolbit and wherein the tool bit swings together with the body with respectto the handgrip held by a user of the power tool, at the same time aswhen the tool bit linearly reciprocates with respect to the body via themotor; an elastic element disposed between the handgrip and the body,wherein the elastic element absorbs vibration transmitted from the bodyto the handgrip by elastically receiving the relative rotation of thehandgrip and the body; and a dynamic vibration reducer disposed in thehandgrip, the dynamic vibration reducer reducing the vibrationtransmitted from the body to the handgrip during cutting operation. 2.The reciprocating power tool as defined in claim 1, wherein the dynamicvibration reducer comprises a single dynamic vibration reducer.
 3. Thereciprocating power tool as defined in claim 1, wherein the elasticelement reduces the tangential force about the pivot while the dynamicvibration reducer reduces the force in the reciprocating direction ofthe saw blade.
 4. The reciprocating power tool as defined in claim 1,wherein the handgrip is detachably coupled to the body and replaceablewith another handgrip.
 5. The reciprocating power tool as defined inclaim 1, further comprising: a switch to turn on and off the motor,wherein the dynamic vibration reducer is provided above the switch. 6.The reciprocating power tool as defined in claim 1, wherein the dynamicvibration reducer has a guide rod and a weight surrounding the guiderod.
 7. The reciprocating power tool as defined in claim 6, wherein theweight is slidably movable on the guide rod.
 8. The reciprocating powertool as defined in claim 7, wherein the motor causes the tool bit tolinearly reciprocate by sliding a slider in the longitudinal directionof the power tool, and the weight of the dynamic vibration reducer movesin the same direction with the slider.
 9. The reciprocating power toolas defined in claim 7, wherein the movement of the weight of the dynamicvibration reducer tangentially coincides with the rotational movement ofthe handgrip about the pivot.
 10. The reciprocating power tool asdefined in claim 1, wherein the elastic element is declined forwardlyalong an axis that is angled such that it declines forwardly withrespect to the direction of reciprocating linear motion of the tool bit.11. The reciprocating power tool as defined in claim 1, wherein, whenthe tool bit held by a user of the power tool linearly reciprocates, thetool bit vertically swings on the pivot together with the body by aninertial force acting upon the body such that an angle of inclination ofthe reciprocating tool bit is changed.
 12. The reciprocating power toolas defined in claim 11, wherein when the tool bit linearly moves in adirection to cut a workpiece, the angle of inclination of the tool bitgradually increases.